Chemokine receptor-mediated delivery directs self-tumor antigen efficiently into the class II processing pathway in vitro and induces protective immunity in vivo.

Nonimmunogenic antigens can be efficiently rendered immunogenic by targeting them to antigen-presenting cells via differentially expressed chemokine receptors. For example, self-tumor or HIV antigens genetically fused with proinflammatory chemoattractants elicit potent immune responses and protective antitumor immunity in mice. Herein we demonstrate that the mechanism by which chemokine fusions elicit responses is efficient uptake, processing, and presentation of antigens via the major histocompatibility complex class II pathway.

Genetic fusions with viral chemokines target delivery of nonimmunogenic antigen to trigger antitumor immunity independent of chemotaxis.

The ideal vaccine carrier should be able to target antigen delivery and possibly recruit antigen-presenting cells (APC) and deliver an activation signal to promote adaptive immune responses. Ligands for chemokine receptors expressed on APC may be attractive candidates, as they can both target and attract APC. To investigate the requirement for APC recruitment, we used a pair of viral chemokines, agonist herpes simplex virus 8-derived macrophage inflammatory protein-I (vMIP-I) and antagonist MC148, which induce and suppress chemotaxis, respectively.